Dissecting galactic bulges in space and time I: the importance of early formation scenarios vs. secular evolution

TL;DR

This study uses high-resolution integral field spectroscopy to analyze the stellar populations and kinematics of three galactic bulges, revealing complex formation histories involving both early formation and secular processes.

Contribution

It provides detailed spatially resolved stellar population analysis of bulges, highlighting the significant role of secular evolution alongside early formation mechanisms.

Findings

Over 50% of stellar mass in bulges predates 10 Gyrs ago.

Younger stellar components are strongly influenced by morphological structures like bars.

Bulge evolution involves complex interplay of formation scenarios beyond mergers alone.

Abstract

The details of bulge formation via collapse, mergers, secular processes or their interplay remain unresolved. To start answering this question and quantify the importance of distinct mechanisms, we mapped a sample of three galactic bulges using data from the integral field spectrograph WiFeS on the ANU 2.3m telescope in Siding Spring Observatory. Its high resolution gratings (R=7000) allow us to present a detailed kinematic and stellar population analysis of their inner structures with classical and novel techniques. The comparison of those techniques calls for the necessity of inversion algorithms in order to understand complex substructures and separate populations. We use line-strength indices to derive SSP-equivalent ages and metallicities. Additionally, we use full spectral fitting methods, here the code STECKMAP, to extract their star formation histories. The high quality of our data allows us to study the 2D distribution of different stellar populations (i.e. young, intermediate, and old). We can identify their dominant populations based on these age-discriminated 2D light and mass contribution. In all galactic bulges studied, at least 50% of the stellar mass already existed 10 Gyrs ago, more than currently predicted by simulations. A younger component (age between 1 to 8 Gyrs) is also prominent and its present day distribution seems to be affected much more strongly by morphological structures, especially bars, than the older one. This in-depth analysis of the three bulges supports the notion of increasing complexity in their evolution, likely to be found in numerous bulge structures if studied at this level of detail, which cannot be achieved by mergers alone and require a non-negligible contribution of secular evolution.